Abstract
In the absence of x-ray structures of sodium and calcium channels their homology models are used to rationalize experimental data and design new experiments. A challenge is to model the outer-pore region that folds differently from potassium channels. Here we report a new model of the outer-pore region of the NaV1.4 channel, which suggests roles of highly conserved residues around the selectivity filter. The model takes from our previous study (Tikhonov, D. B., and Zhorov, B. S. (2005) Biophys. J. 88, 184-197) the general disposition of the P-helices, selectivity filter residues, and the outer carboxylates, but proposes new intra- and inter-domain contacts that support structural stability of the outer pore. Glycine residues downstream from the selectivity filter are proposed to participate in knob-into-hole contacts with the P-helices and S6s. These contacts explain the adapted tetrodotoxin resistance of snakes that feed on toxic prey through valine substitution of isoleucine in the P-helix of repeat IV. Polar residues five positions upstream from the selectivity filter residues form H-bonds with the ascending-limb backbones. Exceptionally conserved tryptophans are engaged in inter-repeat H-bonds to form a ring whose π-electrons would facilitate passage of ions from the outer carboxylates to the selectivity filter. The outer-pore model of CaV1.2 derived from the NaV1.4 model is also stabilized by the ring of exceptionally conservative tryptophans and H-bonds between the P-helices and ascending limbs. In this model, the exceptionally conserved aspartate downstream from the selectivity-filter glutamate in repeat II facilitates passage of calcium ions to the selectivity-filter ring through the tryptophan ring. Available experimental data are discussed in view of the models.
Highlights
Voltage-gated ion channels are involved in the control of many physiological functions
The calcium channel tryptophan, W2p52 did not disappear during the evolution, but apparently shifted one position in the N-terminal direction to become exceptionally conserved W2p51 (Fig. 1B). These data allow us to suggest that the exceptionally conserved tryptophans in calcium channels play roles similar to those that we proposed for sodium channels
We suggest that the evolutionary conservation of these residues is due to their participation in maintaining the outer-pore structure and their involvement in the ion permeation
Summary
Voltage-gated ion channels are involved in the control of many physiological functions. Voltage-gated potassium, sodium, and calcium channels are believed to share a generally similar folding of transmembrane helices and P-helices [2, 3]. Despite the fact that similar experimental data sets underlie the models, they differ significantly in terms of mutual disposition and orientation of the pore helices and conformations of the ascending limbs. An explanation for this difference is flexibility of side chains in the ascending limbs that according to experimental data interact with specific toxin moieties. The toxin-channel distance constraints, which are derived from experiments, are insufficient for elaboration of an unambiguous model of the outer pore
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